Metal oxide materials

ABSTRACT

The invention provides certain novel metal oxide materials which exhibit superconductivity at elevated temperatures and/or which are useful in electrode, electrolyte, cell and sensor applications, or as electrochemical catalysts. The metal oxide materials are generally within the formula 
     
       
         R n+1−u−s A u M m+e Cu n O w   (1) 
       
     
     where n≧0 and n is an integer or a non-integer, 1≦m≦2, 0≦s≦0.4, 0≦e≦4, and 2n+(1/2)&lt;w&lt;(5/2)n+4, with the provisos that u is 2 for n≧1, u is n+1 for 0≦n≦1 and where 
     R and A are each any of or any combination of Y, La, Ce, Pr, Nd, Sm, Eu, Gd, Dy, Ho, Er, Tm, Yb, Lu, Ca, Sr, Ba, Li, Na, K, Rb or Cs; M is any of or any combination of Cu, Bi, Sb, Pb, Tl or any other transition metal; Cu is Cu or Cu partially substituted by any of or any combination of Bi, Sb, Pb, Tl or any other transition metal; O is O or O partially substituted by any of N, P, S, Se, or F; and wherein the structure of the materials is characterised by distorted or undistorted substantially square planar sheets of CuO 2  when n&gt;0 and distorted or undistorted substantially square sheets of R for n&gt;1.

The invention comprises certain novel metal oxide materials which exhibit superconductivity at elevated temperatures and/or which are useful as electrodes or electrolytes in electrochemical cells, sensors, and as catalysts.

It is known that certain classes of metal oxide will exhibit the phenomenon of superconductivity below a particular critical temperature referred to as T_(c). These include as prototypes BaPb_(2−x)Bi_(x)O_(3−d), Ba_(2−x)Sr_(x)CuO_(4−d), YBa₂Cu₃O_(7−d) as described in The Chemistry of High Temperature Superconductors, ed. by Nelson et al, American Chem. Soc. 1987, and Bi₂Sr₂CaCu₃O_(5−d) as described by Subramanian et al, Science 239, 1015 (1988). We have identified this last material as the n=2 member in a homologous series of approximate formula Bi₂(Sr,Ca)_(n+1)Cu_(n)O_(2n+4+d), n=0, 1, 2, 3, . . . , obtained by inserting an additional layer of Ca and an additional square planar layer of CuO₂ in order to obtain each higher member. These materials often exhibit intergrowth structures deriving from a number of these homologues as well as Bi substitution on the Sr and Ca sites. T_(c) is observed to rise as n increases from 1 to 2 to 3. The material YBa₂Cu₄O_(8+d) has a layered structure similar to the n=2 member of this series Bi₂Sr₂CaCu₂O_(8+d) and we expect therefore that YBa₂Cu₄O_(8−d) belongs to similar series. One such serial could be obtained by insertion of extra Y—CuO₂ layers resulting in the series of materials R_(n)Ba₂Cu_(n+3)O_(3.5+2.5n−d), n=1, 2, 3, . . . and another by insertion of extra Ca—CuO₂ layers resulting in the series RBa₂Ca_(n)Cu_(n+4)O_(8+2n−d), n=1, 2, . . . By analogy it may be expected that T_(c) in these two series should rise with the value of n.

Binary, ternary or higher metal oxide materials containing as cations one or more alkali earth elements, such as these materials and having high oxygen-ion mobility may also be used as electrodes, electrolytes and sensors for electrochemical applications. The oxygen-ions will move through such an electrolyte material under an applied electrical field allowing the construction of oxygen pumps for catalysis and other oxidizing or reduction processes involving the supply or extraction of atomic oxygen. The oxygen-ions will also move through such an electrolyte material under a concentration gradient allowing the construction of batteries, fuel cells and oxygen monitors. For these materials to act effectively as electrolytes in such applications it is necessary that they have high oxygen-ion mobility through the atomic structure of the materials and at the same time have a low electronic conductivity so that the dominant current flow is by oxygen-ions and not electrons. For these materials to act effectively as electrodes in such applications it is necessary that they have a high electronic conductivity as well as a high oxygen-ion mobility so that electrons which are the current carried in the external circuit may couple to oxygen-ions which are the current carrier in the internal circuit. Electrochemical cells including fuel cells, batteries, electrolysis cells, oxygen pumps, oxidation catalysts and sensors are described in “Superionic Solids” by S Chandra (North Holland, Amsterdam 1981).

Solid electrolytes, otherwise known as fast-ion conductors or superionic conductors have self diffusion coefficients for one species of ion contained within their crystalline structure ranging from 10⁻⁷ to 10⁻⁵ cm²/sec. A diffusion coefficient of about 10⁻⁵ m²/sec is comparable to that of the ions in a molten salt and thus represents the upper limit for ion mobility in a solid and is tantamount to the sublattice of that particular ion being molten within the rigid sublattice of the other ions present. Such high diffusion mobilities translate to electrical conductivities ranging from 10⁻² to 1 S/cm, the latter limit corresponding to that commonly found in molten salts. The n=0 member of the series Bi_(2+e−x)Pb_(x)(Sr,Ca)_(n+1−s)Cu_(n)O_(2n+4+d) and various substituted derivatives are identified as solid electrolytes with high oxygen-ion mobility. The n=1, 2 and 3 members of the series may have high oxygen-ion mobility as well as high electron conductivity and thus are potentially applicable as electrode materials.

The invention provides certain novel metal oxide materials which exhibit superconductivity at low temperatures and/or which are useful in such electrode, electrolyte, cell and sensor applications, or as electrochemical catalysts.

In broad terms the invention comprises metal oxide materials within the formula

R_(n+1−u−s)A_(u)M_(m+e)Cu_(n)O_(w)  (1)

where n≧0 and n is an integer or a non-integer, 1≦m≦2, 0≦s≦0.4, 0≦e≦4, and 2n+(1/2)≦w≦(5/2)n+4, with the provisos that u is 2 for n≧1, u is n+1 for 0≦n<1

and where

R and A are each any of or any combination of Y, La, Ce, Pr, Nd, Sm, Eu, Gd, Dy, Ho, Er, Tm, Yb, Lu, Ca, Sr, Ba, Li, Na, K, Rb or Cs,

M is any of or any combination of Cu, Bi, Sb, Pb, Tl or any other transition metal,

Cu is Cu or Cu partially substituted by any of or any combination of Bi, Sb, Pb, Ti or any other transition metal,

O is O or O partially substituted by any of N, P, S, Se, or F.

and wherein the structure of the materials is characterised by distorted or undistorted substantially square planar sheets of CuO₂ when n>0 and distorted or undistorted substantially square sheets of R for n>1.

excluding where M is Bi, R is Ca and Sr, A is Sr and Ca, and s and e are 0 and where n=1, the material Bi₂(Sr_(1−x)Ca_(x))₂CuO_(8−d) with 0≦x≦0.3, and where n=2 the material Bi₂(Sr_(1−x)Ca_(x))₃Cu₂O_(10−d) with 0.6≦x≦0.33

and excluding RBa₂Cu₃O_(7−d)

and excluding, where R is as above excluding Ca, Sr, Ba, Li, Na, K, Rb or Cs, the material having formula

RBa₂Cu₄O_(8−d).

The n=1, 2, 3, 4, 5, . . . materials have pseudo-tetragonal structures with lattice parameters a, b and c given by 5.3 Å≦a,b≦5.5 Å and c=18.3±v+(6.3±v′)n Å where 0≦v, v′≦0.3. The n=0 material extends over the solubility range 0≦e≦4 and has orthorhombic or rhombohedral symmetry with lattice parameter c=19.1±v Å.

Preferred materials of the invention are those of formula (1) wherein m is 2 and R is Ca and R is predominantly Bi and having the formula

 Bi_(2+e−x)L_(x)Ca_(n+1−u−s)A_(u)Cu_(n)O_(w)  (2)

where L is any of or any combination of Pb, Sb, or Ti, and 0≦x≦0.4.

More preferred materials of the invention are those of formula (2) where n≧1 and 0≦e≦0.4 and having the formula

Bi_(2+e−x)L_(x)Ca_(n+y−1−s)Sr_(2−y)A_(z)Cu_(n)O_(2n+4+d)  (3)

and where 0≦z≦0.4, −2≦y≦2, and −1≦d≦1.

Materials or formula (3) of the invention wherein n is 3 have the formula

Bi_(2+e−x)L_(x)Ca_(2+y−s)Sr_(2−y)A_(z)Cu₃O_(10+d).  (4)

Preferably in the n=3 materials of formula (4) L is Pb and 0≦x≦0.4 and −1≦y, d≦1. A may preferably be Y or Na and 0≦z≦0.4 and preferably 0, with preferably 0.5≦y≦0.5 and −1≦d≦1. Preferably d is fixed in a range determined by annealing in air at between 300° C. and 550° C., or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to.annealing in air at between 300° C. and 550° C. Most preferably 0.2≦e, s≦0.3, 0.3≦x≦0.4 and −0.1≦y≦0.1.

Especially preferred n=3 materials of the invention are Bi_(1.9)Pb_(0.35)Ca₂Sr₂Cu₃O_(10+d), Bi_(2.1)Ca₂Sr₂Cu₃O_(10+d), preferably wherein d is fixed in a range determined by annealing in air at between 300° C. and 550° C., or by annealing in an atmosphere at any oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 300° C. and 550° C.

Materials of formula (3) of the invention wherein n is 2 have the formula

Bi_(2+e−x)L_(x)Ca_(1+y−s)Sr_(2−y)A_(z)Cu₂O_(8+d)  (5)

where −1≦d≦1.

Preferably in the n=2 materials of formula (5) L is Pb and 0<x and most preferably 0<x≦0.4, z is 0, and −1≦y, d≦1. A may preferably be Y or Na; where A is Y preferably 0<z≦0.4 and most preferably 0<z≦0.1 and where A is Na preferably 0<z≦0.4, x is 0, and −1≦y, d≦1; in both cases preferably d is fixed in a range determined by annealing in air at between 700° C. and 830° C. or in 2% oxygen at between 600° C. and 800° C., or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 700° C. and 800° C.

A preferred n=2 material is that of formula (5) wherein L is Pb, and where 0<x≦0.4, z is 0, 0≦e, s≦0.25, y is −0.5, and d is fixed in a range determined by annealing the material in air between 600° C. and 800° C., or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 700° C. and 800° C.

A further preferred n=2 material is that of formula (5) wherein L is Pb, and where 0<x≦0.4, z is 0, 0≦e, s≦0.25, y is 0, and d is fixed in a range determined by annealing in air at between 700° C. and 830° C. or in 2% oxygen at between 600° C. and 800° C. or by annealing in an atmosphere and at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 700° C. and 830° C.

A further preferred n=2 material is that of formula (5) wherein L is Pb, and where 0≦e, s≦0.25, 0≦x≦0.4, y is 0.5, z is 0, and d is fixed in a range determined by annealing in air at between 450° C. and 700° C. or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 450° C. and 700° C.

A further preferred n=2 material is that of formula (5) having the formula Bi_(2.1+e)Pb_(0.2)Ca_(1−s)Sr₂Cu₂O_(8+d) and where 0≦e, s≦0.2 and d is fixed in a range determined by annealing in 2% oxygen at between 770° C. and 830° C. or in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in 2% oxygen at between 770° C. and 830° C.

A further preferred n=2 material is that of formula (5) having the formula Bi_(2+e)Ca_(1+y−s)Sr_(2−y)Cu₂O_(8+d) where −0.5≦y≦0.5 and 0<e, s≦0.25 and most preferably wherein y is −0.5 or most preferably 0, and d is fixed in a range determined by annealing in air at between 600° C. and 800° C. or by annealing in an atmosphere at an oxygen partial pressure and temperature equivalent to annealing in air at between 600° C. and 800° C.; of the above formula or wherein y is 0.5, and d is fixed in a range determined by annealing the material in air at between 450° C. and 700° C. or in an atmosphere other than air at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 450° C. and 700° C.

Materials of formula (1) of the invention wherein n is 1 have the formula

Bi_(2+e−x)L_(x)Ca_(y−s)Sr_(2−y)A_(z)CuO_(6+d)  (6)

where 0≦y≦1 and −1≦d≦1

Preferably in the n=1 materials of formula (6) L is Pb and 0≦x≦0.4. A is preferably Na and 0<z≦0.4.

A preferred n=1 material is that of formula (6) wherein L is Pb, and where 0<x≦0.4, 0≦e, s≦0.25 y is 0.7, and z is 0.

A further preferred n=1 material is that of formula (6) wherein L is Pb, and where 0≦e, s≦0.25, 0≦x≦0.4, y is 1 and z is 0.

A further preferred n=1 material is that of formula (6) wherein L is Pb, and where z is 0, 0≦e, s≦0.25 0.3≦x≦0.4, and 0.5≦y≦0.7.

A preferred n=1 material is

Bi_(1.85)Pb_(0.35)Ca_(0.4)Sr_(1.4)CuO_(6+d).

A preferred n=1 material is Bi_(2+e)Ca_(y−s)Sr_(2−y)CuO_(6+d) where 0<e, s≦0.25 and y is 1 and d is fixed in a range determined by annealing in air at between 300° C. and 500° C. or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 300° C. and 500° C.

A further preferred n=1 material is that of formula (6) where y is 0.67, and d is fixed in a range determined by annealing in air at between 400° C. and 600° C. or by annealing in an atmosphere at an oxygen pressure or partial pressure and temperature equivalent to annealing in air at between 400° C. and 600° C.

Materials of formula (1) of the invention where n is 0 have the formula

Bi_(2+e−x)L_(x)A_(1−z)A′_(z)O_(w)  (7)

where 0≦x≦0.4 and 0≦z≦1 with the proviso that z is not 0 when x is 0, and where 0≦e≦4. A_(1−z)A′_(z) is the combinational form of A as defined for formula (1).

Preferably in the n=0 materials of formula (7) wherein L is Pb and preferably A is Ca, Sr, or Ba or any combination thereof. Where A is Ca preferably A′ is Sr, Ba, Na or Y, or any combination thereof. Where A is Sr preferably A′ is Ba, Na or K, or any combination thereof. Most preferably A is Ba and A′ is K.

Specific materials of the invention include

Bi_(2+e)Sr_(0.8)Na_(0.2)O_(4+d), Bi_(2+e)Ba_(0.5)K_(0.2)O_(4+d),

Bi_(2+e)Ca_(0.5)Sr_(0.5)O_(4+d), Bi_(2+e)Ba_(0.5)Sr_(0.5)O_(4+d),

Bi_(1.9+e)Pb_(0.1)SrO_(4+d), and Bi_(1.9+e)Pb_(0.1)BaO_(4+d), with 0≦e≦4 and 3≦d≦10.

The invention encompasses materials of formula (7) wherein n≧2, s=0 and M is Cu or Cu substituted by any of or any combination of Bi, Sb, Pb, Ti or any other transition metal, and having the formula

R_(n−1)A₂Cu_(m)Cu_(n)O_(w)  (8)

Preferably in materials of formula (8) of the invention A is Ba, m is 1 or 2, and n is 3, 4, . . . A material of this class may be where m=3/2 and n=2, and having the formula

RBa₂Cu_(3.5)O_(7+d)

where −0.5≦d≦0.5, and where R is Y.

The invention encompasses a material having the formula

Y_(n−1)Ba₂Cu_(n+1)O_((5/2)n+3/2+d)

where −1≦d≦1 and n is 3, 4, 5, . . . ,

a material having the formula

Y_(n−1)Ba₂Cu_(n+2)O_((5/2)n+5/2+d), and,

a material having the formula

RBa₂Ca_(n−2)Cu_(n+2)O_((5/2)n+5/2+d)

wherein n is 3, 4, 5, . . . preferably where R is Y.

The materials of the invention may be formed as mixed phase or intergrowth structures incorporating structural sequences from a number of the above described materials also including sequences from the material RBa₂Cu₃O_(7−d) and its derivatives. For example, this includes RBa₂Cu_(3.5)O_(7.5−d) comprising, as it does, approximately alternating sequences of RBa₂Cu₃O_(7−d) and RBa₂Cu₄O_(8−d). This also includes materials with general formula (1) with n taking non-integral values allowing for the fact that, for example, a predominantly n=2 material may have n=1 and n=3 intergrowths. This also includes materials with general formula (1) with n taking non-integral values allowing for ordered mixed sequences of cells of different n values, for example, n=2.5 for alternating sequences of n=2 and n=3 slabs.

Typically, the materials of the invention may be prepared by solid state reaction of precursor materials such as metals, oxides, carbonates, nitrates, hydroxides, or any organic salt or organo-metallic material, for example, such as Bi₂O₃, Pb(NO₃)₂, Sr(NO₃)₂, Ca(NO₃)₂ and CuO for BiPbSrCaCuO materials. The materials of the invention may also be prepared by liquid flux reaction or vapour phase deposition techniques for example, as will be known to those in the art. Following forming of the materials oxygen loading or unloading as appropriate to achieve the optimum oxygen stoichiometry, for example for superconductivity, is carried out. The above preparation techniques are described in “Chemistry of High Temperature Superconductors”—Eds. D L Nelson, M S Whittingham and T F George, American Chemical Society Symposium Series 351 (1987); Buckley et al, Physica C156, 629 (1988); and Torardi et al Science 240, 631 (1988), for example. The materials may be prepared in the form of any sintered ceramic, recrystallised glass, thick film, thin film, filaments or single crystals.

In order to achieve maximum strength and toughness for the materials, it is important that they are prepared to a density close to the theoretical density. As prepared by common solid-state reaction and sintering techniques, densities of about 80% theoretical density can readily be achieved. Higher densities may be achieved by, for example, spray drying or freeze drying powders as described for example in Johnson et al, Advanced Ceramic Materials 2, 337 (1987), spray pyrolysis as described for example in Kodas et al, Applied Physics Letters 52, 1622 (1988), precipitation or sol gel methods as described for example in Barboux et al J. Applied Physics 63, 2725 (1988), in order to achieve very fine particles of dimension 20 to 100 mm. After die-pressing these will sinter to high density. Alternatively, to achieve higher densities one may hot press, extrude, or rapidly solidify the ceramic material from the melt after solid state reaction or grow single crystals.

Preparation of the materials of the invention may be carried out more rapidly if in preparation of the materials by solid state reaction of precursor material any or all of the cations in the end material are introduced as precursors in the nitrate or hydroxide forms for rapid reaction of bulk material in the nitrate or hydroxide melt. Both the temperature and duration of the preparation reaction may be lowered by using nitrate or hydroxide precursors to introduce the cations. Melting of the nitrate and/or hydroxide precursors allows intimate atomic mixing prior to decomposition and efflux of oxides of nitrogen.

After preparation the materials may be sintered or (re-)ground to small particles and pressed to shape and sintered as desired to form the end material for use, as is known in the art and/or annealed to relieve stresses and increase strength and toughness as is similarly known in the art for the unsubstituted materials. The materials after preparation may as necessary be loaded on unloaded with oxygen to achieve the optimum stoichiometry for superconductivity, optimised oxygen mobility, or other material properties. As stated, for n=2 BCSCO materials for example this generally requires oxygen unloading into the materials and with known technique this is generally carried out by annealing at 700° C. to 830° C. in air over 1 to 4 hours followed by rapid quenching into liquid nitrogen, for example. Most suitably, oxygen loading or unloading is carried out during cooling from the reaction temperatures immediately after the preparation reaction, where the materials are prepared by solid state reaction for example. Alternatively and/or additionally oxygen loading may be carried out during sintering or annealing in an oxygen containing atmosphere at an appropriate pressure or partial pressure of oxygen. Without loss of generality the materials may be annealed, cooled, quenched or subjected to any general heat treatment incorporating AgO or Ag₂O as oxidants or in controlled gaseous atmospheres such as argon, air or oxygen followed by rapid quenching so as to control the oxygen stoichiometry of the novel materials, the said stoichiometry being described by the variables w or d. The materials may be used as prepared without necessarily requiring oxygen loading or unloading for forming electrodes, electrolytes, sensors, catalysts and the like utilising high oxygen mobility property of the materials.

The invention is further described with reference to the following examples which further illustrate the preparation of materials in accordance with the invention. In the drawings which are referred to in the examples:

FIG. 1 shows a graph of electrical conductivity as a function of inverse temperature. Open circles are for heating and closed circles are for cooling when measurements are made at 1592 Hz. The triangles refer to the equivalent conductivity for the mid-frequency relaxation peak (upward pointing triangles) and the high-frequency peak (downward pointing). Open triangles and the circles refer to Bi₂SrO₄ and the full triangles refer to Bi₂Sr_(0.9)Na_(0.1)O₄.

FIG. 2a shows a Cole-Cole plot of Z″ versus Z′ measured at 644° C. for Bi₂SrO₄ in oxygen.

FIG. 2b shows a Cole-Cole plot of Z″ versus Z′ measured at 644° C. for the Bi₂SrO₄ sample of FIG. 2a in nitrogen.

FIG. 2c shows a Cole-Cole plot of Z″ versus Z′ measured at 644° C. for the Bi₂SrO₄ sample of FIG. 2b in oxygen.

FIG. 3a shows a Cole-Cole plot or Z″ versus Z′ measured at 736° C. for Bi₂SrO₄ in oxygen.

FIG. 3b shows a Cole-Cole plot of Z″ versus Z′ measured at 736° C. for the Bi₂SrO₄ sample of FIG. 3a in nitrogen.

FIG. 3c shows a Cole-Cole plot of Z″ versus Z′ measured at 736° C. for the Bi₂SrO₄ sample of FIG. 3b in oxygen.

FIG. 4 shows V₁₂/ln(p₁/p₂) plotted against temperature where V₁₂ is the potential developed over a concentration cell using Bi₂SrO₄ as the electrolyte with oxygen partial pressures of p₁ and p₂ on either side of the cell.

FIG. 5 shows a plot of the conductivity measured at 1592 Hz as a function of temperature for Bi₂Sr_(0.5)Ca_(0.5)O₄ (solid symbols) and for Bi₂SrO₄ (open symbols).

FIG. 6a shows a plot of zero resistance T_(c) against the annealing temperature in air from which the sample was quenched into liquid nitrogen. (X) Bi_(2.1)Ca₂Sr₂Cu₃C₁₀; (∘) Bi_(2.1)CaSr₂Cu₂O₅; (+) Bi_(2.1)Ca_(0.5)Sr_(2.5)Cu₂O₅; (Δ) Bi_(2.1)Ca_(1.5)Sr_(1.5)Cu₂O₅; () Bi_(2.1)CaSr₂Cu₂O₅ quenched from 2% oxygen; (□) Bi_(2.1)Ca_(0.67)Sr_(1.33)CuO₆; (⋄) Bi_(2.1)CaSrCuO₆.

FIG. 6b shows a plot of maximum T_(c) versus n the number of Cu layers.

FIG. 7 shows a plot of the XRD diffraction patterns for Bi_(1.88)Pb_(0.35)Ca_(0.4)Sr_(1.4)CuO_(6+d) obtained using CoKa radiation.

FIGS. 8a and 8 b show the XRD patterns for Pb-substituted compounds n=2 x=0.2 and n=3 x=0.35, respectively.

FIGS. 9a and 9 b show the temperature dependence of the resistivity for Pb-substituted n=2 material x=0.2 and x=0.3, respectively.

FIG. 10 shows the zero resistance T_(c) obtained as a function of anneal temperature for the n=2 and n=3 unsubstituted (open symbols, x=0) and Pb-substituted samples (filled symbols). ∘:n=2, x=0.2, 21% oxygen; □:n=2, x=0.2 2% oxygen; Δ:n=2, x=0.2 0.2% oxygen; and ⋄:n=3, x=0.35, 21% oxygen.

FIG. 11a shows the temperature dependence of resistivity for n=2 and x=0.2 reacted at 800° C. then annealed in air at 800, 700, 600 and 500° C. before quenching into liquid nitrogen.

FIG. 11b shows a typical curve for the unsubstituted x=0 material.

FIG. 11c shows the temperature dependence of the resistivity for n=3 and x=0.35.

FIG. 11d shows typical behaviour for x=0.

FIGS. 12a and 12 b show the temperature dependence of the resistivity for Bi_(2.1)CaSr₂Cu₂O₃ annealed in air at various temperatures shown in ° C. for 5% Y substitution and no substitution, respectively.

FIG. 13 shows a plot of the zero resistance T_(c) as a function of air anneal temperature for 5% Y-substituted Bi_(2.1)CaSr₂Cu₂O₈ (solid hexagons). For comparison, the T_(c) values for unsubstituted n=1, n=2 and n=3 are also shown (open data points).

FIG. 14 shows a plot of the temperature dependence of the resistivity for the nominal composition Bi_(1.9)Pb_(0.35)Ca_(0.9)Y_(0.1)Sr₂Cu₂O₅ annealed and quenched at 500° C., 700° C. and 820° C. showing no change in T_(c).

FIGS. 15a and 15 b show a series of resistivity plots against temperature for n=3 and n=2, respectively, after annealing in air and then quenching into liquid nitrogen. The annealing temperatures are indicated in ° C.

FIGS. 16a, 16 b, and 16 c show the [5{overscore (5)}1] zone axis electron diffraction patterns for n=1, n=2 and n=3, respectively, indexed on a 5.4 Å×5.4 Å×2c Å cell where c=18.3+6.3n Å.

EXAMPLE 1 (N=0)

Samples of composition Bi_(2+e)SrO_(4+d) with e=0, 0.25, 0.5, 1.25 and 2 were prepared by solid-state reaction of Bi₂O₃ and SrCO₃ at 740° C. in gold crucibles for 15 hrs. All samples were quenched from the furnace into liquid nitrogen and investigated by x-ray diffraction, electron diffraction and SEM electron-beam x-ray analysis to confirm compositions of crystallites. The e=0 material was white-yellow of orthorhombic structure with lattice parameters a=4.26 Å, b=8.10 Å and c=19.38 Å while the remaining solid-solution compositions were yellow with rhombohedral symmetry and lattice parameters varying smoothly with composition given by a=9.852−0.09e Å and α=23.28+0.2e°.

FIG. 1 shows the electrical conductivity measured at 1592 Hz for the e=0 material. This shows a rapid rise in conductivity above 700° C. towards values typical of solid-state electrolytes. The rapid rise coincides with a broad endothermic DTA peak indicative of a diffuse fast-ion transition. Complex impedance spectroscopy reveals three separate relaxation peaks: a broad low-frequency peak with effective capacitance in the microFarad range which is attributable to inter-granular impedance; and two higher frequency peaks attributable to oxygen-ion relaxation. The conductivities associated with these two high frequency peaks are plotted as the open triangles in FIG. 1. FIGS. 2a, 2 b, and 2 c show Cole-Cole plots at 644° C. in oxygen (FIG. 2a), then in nitrogen, then in oxygen, while FIGS. 3a, 3 b, 3 c show the same sequence at 736° C. In nitrogen a distinct Warburg-type impedance appears with the characteristic 45° slope. This arises from the diffusive depletion of oxygen ions at the surface when in an oxygen-free ambient and confirms the origin of the conductivity in oxygen-ion transport. A concentration cell was constructed using a sintered pellet of e=0 material over which a difference in oxygen partial pressure was maintained while the cell emf was measured. If the transport coefficient is dominated by oxygen-ion mobility rather than electron transport then the emf V₁₂ is given by the Nernst equation

V ₁₂=(RT/nF)ln(p ₁ /p ₂)

Here R is the gas constant, T is temperature in degrees Kelvin, F is the Faraday constant and n (=4) is the number of moles of electron charge produced by one mole of O₂. p₁ and p₂ are the partial pressures of oxygen on either side of the cell. FIG. 4 shows V₁₂/ln(p₁/p₂) plotted against T and the data follows the ideal theoretical line with slope R/nF, thus confirming that the transport number is dominated by the oxygen-ion transport number.

EXAMPLE 2 (n=0)

Samples of composition Bi₂Sr_(1−z)Na_(z)O_(4+d) for z=0.1 and z=0.2 were prepared at 770° C. by reaction of the carbonates or Na and Sr with Bi₂O₃ for 15 hrs. XRD showed that these were single phase exhibiting the same orthorhombic structure as the unsubstituted e=0 material. The conductivities associated with the two high frequency complex impedance relaxations are plotted as solid triangles and these show enhancements in conductivity above that for unsubstituted material of 10 times and 30 times respectively.

EXAMPLE 3 (n=0)

Samples of composition Bi₂Sr_(1−z)Ca_(z)O_(4+d) for z=0.33 and z=0.5 were prepared at 770° C. by reaction of the carbonates of Ca and Sr with Bi₂O₃ for 15 hrs. XRD showed that these were single phase materials exhibiting the same hexagonal structure as occurs in the unsubstituted e>0 solid-solubility range, Lattice c-parameters obtained were 19.14 Å (z=0.33) and 19.06 (z=0.5). In addition, electron diffraction reveals the existence of a superstructure in the basal plane as evidenced by hexagonal satellites encircling each principal diffraction spot. For z=0.33 the superstructure length is 2.76 times the a-parameter. FIG. 5 shows conductivity measured at 1592 Hz for z=0.5 (solid symbols) and this is compared with the unsubstituted z=0 conductivity (open Symbols) and Y-stabilised zirconia. Over much of the range the conductivity is enhanced by Ca-substitution by a factor of 100 times and is comparable to Y-zirconia.

EXAMPLE 4 (n=0)

Samples of composition Bi_(2+x−y)Pb_(y)SrO_(w) with 0≦x≦0.2 and y=0.2 and y=0.4 were prepared by stoichiometric reaction of Bi₂O₃, SrCO₃ and PbO at 770° C. and quenched into liquid nitrogen producing a bright yellow sintered material.

The structure as prepared was predominantly orthorhombic with the same structure as the unsubstituted material. When annealed and quenched from 500° C. the rhombohedral structure of the unsubstituted solid-solution was adopted and the colour became brown/green. Additional phases were not evident indicating complete substitution at the y=0.4 level. Impedance spectroscopy showed that the mid-and high-frequency relaxation peaks overlapped, producing a single broadened relaxation peak. The conductivity associated with this peak measured during heating of the as prepared material increased with Pb-substitution but on cooling the conductivity remained high.

EXAMPLE 5 (n=1)

Samples corresponding to the starting composition Bi_(z)Sr_(2−x)Ca_(x)CuO_(6+d) were prepared by reacting carbonates of Sr and Ca with the oxides or Bi and Cu at temperatures between 780 and 830° C. for periods of time ranging from 1 to 12 hrs. The n=1 phase is promoted by short reaction times (1 to 2 hrs), temperatures near 800° C. and lower calcium content. We could not prepare the calcium-pure phase x=2, but nearly single-phase material was obtained for s=0, 0.67 and 1.0. The structure was pseudotetragonal with lattice parameters, respectively of a=5.414 Å and c=24.459 Å, a=5.370 Å and c=24.501 Å, and a=5.370 Å and c=24.287 Å. For s=0.67 and s=1.0 incommensurate superlattice structures in the b-direction were observed with dimension ranging from 4.3 to 5.3 times the a-parameter.

Samples were annealed to equilibrium oxygen stoichiometry at various temperatures in air, then rapidly quenched from the furnace into liquid nitrogen. The DC electrical resistivity was measured with a four terminal technique and the zero-resistance T_(c) is plotted in FIG. 6a with squares and diamonds as a function of anneal temperature. T_(c) evidently passes through a Maximum corresponding to the optimum oxygen stoichiometry.

The true c-axis length may be twice the figure quoted above due to a two-times c-axis superstructure. Electron diffraction patterns interpreted as [5{overscore (5)}1] zone-axis patterns may be uniquely indexed on a 5.4 Å×5.4 Å×49 Å unit cell. The same applies to all other n=1, 2 and 3 electron diffraction patterns investigated suggesting a general unit cell of 5.4 Å×5.4 Å×2c Å where c is approximately 18.3+6.3n Å.

EXAMPLE 6 (n=1)

Samples of nominal composition Bi_(1.8)Pb_(0.2)Sr_(1.3)Ca_(0.7)CuO_(6+d), Bi_(1.8)Pb_(0.2)SrCaCuO_(6+d), and Bi_(1.9)Pb_(0.36)Sr_(1.3)Ca_(0.7)CuO_(6+d), were prepared by reacting stoichiometric proportions of Bi₂O₃, Pb(NO₃)₂, Sr(NO₃)₂, Ca(NO₃)₂ and CuO. The n−1 materials are favoured by short reaction times and as a consequence the nitrates are advantageous as they allow homogeneous and rapid mixing in the nitrate melt. The precursor materials were milled, pressed into pellets and reacted at 800° C. for 15 minutes, remilled, pressed into pellets and sintered for 1 hr at the same temperature. The resultant materials were very nearly single phase n=1 materials. The first of the compounds listed above was apparently tetragonal with parameters a=5.355 Å and c=24.471, but this material and even more predominantly the third material with x=0.35 and y=0.7 showed the presence of particles of composition Bi_(1.85)Pb_(0.35)Sr_(1.4)Ca_(0.4)CuO_(6+d). By reacting precursors of this composition good phase-pure material was obtained as shown by FIG. 7. Impurity peaks are indicated by dots. This material is orthorhombic with parameters a=5.313 Å, b=5.391 Å and c=24.481 Å, and, moreover it is semiconducting.

EXAMPLE 7 (n=2)

Samples of nominal composition Bi_(2.1)Sr_(2−y)Ca_(1+y)Cu₂O_(8+d), with y=−0.5, −0.25, 0 and 0.5 were prepared using stoichiometric proportions of the carbonates of Sr and Ca and the oxides of Bi and Cu reacted at temperatures between 860 and 870° C. for a to 15 hrs. The resulting material was ground, milled, pressed into pellets and sintered for another 8 to 15 hrs at 860 to 870° C. in air. This procedure produced very nearly single-phase material with a systematic variation in lattice parameters as shown in the table below confirming the intersubstitution of Sr and Ca. As lattice parameters are dependent upon oxygen stoichiometry determined by annealing temperature and ambient oxygen partial pressure, all these XRD measurements were carried out on materials quenched into liquid nitrogen after annealing for up to 12 hrs at 400° C. in air.

y a c −0.5 5.415 30.908 −0.25 5.410 30.894 0 5.405 30.839 0.5 5.402 30.683

The structure is centred pseudotetragonal as described by Subramanian et al for the y=0 material in Science 239, 1015 (1988). Electron diffraction shows that a 4.75 times incommensurate superstructure exists in the b-direction and as indicated in example 5 there may be a two times superlattice in the c-direction as indicated by the [5{overscore (5)}1] zone axis electron diffraction pattern.

As discussed in example 5 the zero-resistance T_(c) was measured for samples annealed at various temperatures and oxygen partial pressures. The data for anneals in air is plotted in FIG. 6a for the y=−0.5, y=0 and y=0.5 samples by plusses, circles and squares respectively. Again T_(c) maximises at an optimum oxygen stoichiometry for each composition. The solid circles are obtained for anneals of the y=0 material in 2% oxygen and the displacement of the curve confirms that the optimisation is associated with oxygen stoichiometry. We find that the lattice c-parameter varies with anneal temperature but for two different pairs of oxygen partial pressure and anneal temperature which give the same T_(c) the lattice parameters are also the same.

EXAMPLE 8 (n=2)

Samples or composition Bi_(2.2−x)Pb_(x)CaSr₂Cu₂O_(3+d) with x=0, 0.1, 0.2, 0.3, 0.4 and 0.5 were prepared by solid state reaction of Bi₂O₃, CaCO₃ SrCO₃, CuO and PbO for 12 hours at temperatures between 850 and 865° C. The samples were ground, pressed and sintered at the same temperature for a further 12 hours. FIG. 8a shows the XRD trace for x=0.2 which confirms nearly single phase material. Minor impurity peaks are marked by dots. Pb substitution is confirmed by observing a systematic variation in lattice parameters with x, as follows

a=5.405−0.048x Å

and

c=30.830−0.094x Å

Electron beam x-ray analysis of crystallites also confirmed the above compositions. Electron diffraction shows that the b-axis superstructure remains at about 4.75× for 0.4≦x≦0.2. For 0.2≦x≦0.35 this superstructure contracts to 4.5× and a second b-axis superstructure appears with length 7.3×. Substitution for x>0.35 did not occur under the conditions of preparation. Samples were annealed at various temperatures at oxygen partial pressures of 2.1×10⁴ Pa (air), 2×10³ Pa and 2×10² Pa then quenched into liquid nitrogen. The DC resistivity of these samples was measured using a 4-terminal method and AC susceptibility was also measured. FIGS. 9a and 9 b show the resistivity curves for anneals in air for x=0.2 and x=0.3 respectively. T_(c) is seen to decrease with decreasing anneal temperature. FIG. 10 shows the zero resistance T_(c) versus annealing temperature for the three oxygen partial pressures for both x=0 and x=0.2. T_(c) is seen to pass through a maximum for an optimum oxygen content. The maximum T_(c) obtained 93 K. This increase is not due to n−3 material which has a different behaviour also shown in FIG. 10. The optimised T_(c) is maximised at 93 K for x=0.2 and falls 4 K for x=0.3.

The sharpness or the resistive transitions should be noted in FIG. 9a and compared with the typical best curve obtained for x=0 shown in FIG. 11b which exhibits a typical resistive tail. The resistivity curves shown in FIG. 11a are for a x=0.2 sample prepared at the lower temperature of 800° C. The variation in T_(c) as a function of anneal temperature is similar to that shown in FIG. 9a but the normal state resistivity varies differently. Electron microprobe analysis indicated crystallites which were Pb-rich and deficient in Sr and Ca indicating substitution of Pb on the alkali-earth sites.

EXAMPLE 9 (n=2)

Samples of composition Bi_(2.1)Ca_(1−x)R_(x)Sr₂Cu₂O_(8+d) were prepared by solid state reaction of Bi₂O₃, CaCO₃, SrCO₃, CuO and R₂O₃ where R is Y or one of the rare earth elements. Compositions with x=0, 0.05, 0.1, 0.2, 0.4, 0.9 and 1.0 were reacted at temperatures ranging from 860° C. to 900° C. as the rare earth content was increased. Samples were investigated by x-ray diffraction, electron diffraction, IR spectroscopy, thermal gravimetry, and the temperature dependence of resistivity and AC susceptibility. In the following example we deal exclusively with the results for Y-substitution.

The end member x=1 was XRD phase pure and notably has the same structure as Bi_(2.1)CaSr₂Cu₂O_(8+δ) except that the symmetry is reduced from tetragonal to orthorhombic as shown by the splitting of the (200) XRD peak. For Bi_(2.1)YSr₂Cu₂O_(8+δ), annealed in air at 400° C. the lattice parameters are a=5.430 Å, b=5.473 Å and c=30.180 Å. Electron diffraction also reveals the presence of an 8×incommensurate superstructure, of 43.5 Å in the b-direction.

Attempts to study the metal to insulator transition at intermediate substitutions (0<x<1) were prevented by the absence or a substitutional solubility range under the conditions of preparation. In this intermediate range samples were a mixed phase of the x=0 and x=1 end-members except at compositions close to x=0 and x=1 where doping appears to be possible. Interestingly, Y substitution for Ca at the 5% level in Bi_(2.1)CaSr₂Cu₂O_(a+d) appears to raise T_(c). FIG. 12a shows the temperature dependence of the resistivity for such a sample annealed and quenched at different temperatures in order to vary the oxygen stoichiometry, d. This may be compared with the same data shown in FIG. 12b for the x=0 unsubstituted n=2 material. The substitution has both sharpened the resistive transition and raised the zero resistance T_(c). Otherwise the overall behaviour is similar and quite distinct from the n=3 behaviour.

The zero-resistance T_(c) is plotted in FIG. 13 as a function of anneal temperature (solid data points) and evidently T_(c) is maximised at >101 K. FIG. 13 also includes T_(c) data for unsubstituted n=1, n=2 and n=3 material for comparison. Like unsubstituted n=2 the Y-substituted material appears to exhibit a maximum T_(c) for anneals in air above 820° C. However, above this temperature the effects of annealing and quenching are greatly modified by the proximity of a phase transition. In order to achieve maximum T_(c) anneals at an oxygen partial pressure less than that of air is required. The highest zero resistance T_(c) we have observed in this system is 102 K. The elevated T_(c) does not arise from the presence of n=3 material for several reasons:

i) We are able to prepare single-phase n=3 material by Pb-substitution for Bi. Attempts to substitute Y in this material at the 5% level drives the reacted material completely to the n=2 phase together with the binary Ca₂CuO₃. We would therefore hardly expect Y substitution of the n=2 material to promote n=3 material.

ii) The annealing behaviour of T_(c) is similar to that for unsubstituted n=2 material with maxima occurring at 820° C. or higher. The maximum T_(c) for n=3 occurs for anneals at ˜400° C. and for anneals at 820° C. the n=3 T_(c) is as low as 80 K.

Particle by particle analyses by SEM electron beam x-ray analysis indicates that Ca remains fixed at one per formula unit while Sr is slightly depleted. This suggests Y substitution on the Ca-site accompanied by Ca substitution on the Sr-site with the formula Bi_(2.1)(Ca_(0.95)Y_(0.05))(Sr_(1.95)Ca_(0.05))Cu₂O₈. Starting compositions appropriately depleted in Sr indeed offered the best resistive transitions around 100 K with a minimal tail.

It may be that the substitutional solubility tends to occur only at grain boundaries as the sharp resistive transition to zero at 101 K is accompanied by only a small diamagnetic signal in the AC susceptibility commencing at ˜99 K. A sharp roll does not commence until ˜95 K at which point the diamagnetic signal is only about 5% of its fully developed value, The yttrium should therefore be dispersed more uniformly throughout a sample by reaction of nitrates or by melt processing.

This example and particularly the chemical formula deduced for the active phase responsible for raising T_(c) is presented by way of example without loss of generality. Because of the small diamagnetic signal appearing at ˜100 K it may be that the active phase is of another composition and structure incorporating Bi/Ca/Y/Sr/Cu/O.

EXAMPLE 10 (n=2)

Predominantly single phase Bi_(1.9)Pb_(0.35)Ca_(0.9)Y_(0.1)Sr₂Cu₂O_(8+δ) was prepared by solid state reaction of a pressed disc of Bi₂O₃, PbO, CaCO₃, SrCO₃, Y₂O₃ and CuO at 860° C. for 12 hours. By annealing in air at various temperatures then quenching into liquid nitrogen, the normal state resistivity is observed to change as shown in FIG. 14. However, the zero-resistance T_(c) does not change, remaining at just over 90 K for anneals at 500, 700 and 820. This is uncharacteristic of the parent n=2 superconductor as shown in FIG. 12 which required anneals at an oxygen partial pressure less than that of air in order to optimise T_(c) at just over 90 K. The combined Pb- and Y-substitution therefore simplifies the processing requirements for n=2 material.

EXAMPLE 11 (n=3)

A sample of nominal composition BiSrCaCu₃O_(x) was prepared from the carbonates of Sr and Ca, CuO and bismuth oxycarbonate by reacting at 820° C. for 9 hrs, then for 10 hrs at 850° C. then for 10 hrs at 860° C. followed by air-quenching from the furnace. The sample was then annealed in air at temperatures ranging between 400° C. and 800° C. and quenched from the furnace into liquid nitrogen. Four terminal electrical DC resistivity and the AC susceptibility was measured for each anneal temperature. FIG. 15a shows the resistivity curves obtained for this sample after each anneal. The resistivity drop which occurs around 110 K is extrapolated to zero and the deduced zero resistance T_(c) is seen to be maximised at 105 K for anneals at about 400° C. The annealing behaviour is seen to be quite different from that of the n=2 material shown in FIG. 15b.

This sample was pulverised, ground and investigated by XRD, SEM energy dispersive analysis of x-rays (EDX) and TEM electron diffraction. The EDX analyses indicated a high proportion (>70%) of particles with atomic ratios Bi:Sr:Ca:Cu of 2:2:2:3 though many of these particles showed Cu contents more like 2.8 to 2.9 indicating the occurrence of n=2 intergrowths in the n=3 material. Like the n=2 material, crystals or n=3 are platey and under TEM electron diffraction were found to exhibit a 5.4 Å×5.4 Å subcell in the basal plane with the same 19/4 times incommensurate superlattice structure in the b-direction. The diffraction patterns for the [5{overscore (5)}1] zone axis shown in FIGS. 16a, 16 b, and 16 c, respectively, can be indexed on a 5.4 Å×5.4 Å×74 Å cell suggesting a sub-cell c-axis of 37 Å with a superstructure which doubles the c-axis. XRD powder diffraction of this sample showed a broad basal reflection corresponding to a c-repeat of about 18 Å. This leads to the natural conclusion that Bi₂Sr₂Ca₂Cu₃O₁₀ is structurally related to Bi₂Sr₂Ca₁Cu₂O₈ by the insertion of an extra pair of Ca—CuO₂ sheets per unit sub-cell.

EXAMPLE 12 (n−3)

Samples of composition Bi_(2.2−x)Pb_(x)Ca₂Sr₂Cu₃O_(10+d) were prepared by reaction of the oxides of Bi and Cu and the nitrates of Pb, Ca and Sr in stoichiometric proportions for 36 hrs at 860 to 865° C. in air. The XRD pattern shown in FIG. 8b indicates nearly single phase pseudo-tetragonal material with lattice parameters a=5.410 Å and c=37.125 Å. Like the n=2 x=0.2 material, electron diffraction indicates a 4.5 times and a 7.3 times b-axis superlattice structure. The effect on resistivity curves of annealing in air at various temperatures is shown in FIG. 11b and the curve for the x=0 material is shown in the insert. The long resistive tail in the unsubstituted material is removed by Pb-substitution. The effect of annealing temperature in air on the zero resistance T_(c) is shown in FIG. 10 by the diamond shaped points for x=0.35 and x=0.

The foregoing describes the invention including preferred forms and examples thereof. The preparation of derivative materials and forms other than sintered ceramic form, ie. thin films, thick films, single crystals, filiaments and powders other than those specifically exemplified will be within the scope of those skilled in the art in view of the foregoing. The scope of the invention is defined in the following claims. 

What is claimed is:
 1. A metal oxide material having the formula Bi_(x)(Sr,Ca)₄Cu₃O_(10+δ), wherein: x is about 2.1; Bi may be partially replaced by Pb; Sr and Ca can be replaced in part by any alkali metal, alkali earth metal, or a combination thereof; and Cu can be replaced in part by Ag, Bi, Pb or Tl.
 2. A metal oxide material according to claim 1 wherein δ is fixed in a range determined by annealing in air at about 500° C.
 3. A metal oxide material as set forth in claim 1 wherein δ is fixed by annealing said metal oxide material at a temperature of 300-550° C. in air or at an oxygen pressure or partial pressure and temperature equivalent to annealing in air within said temperature range.
 4. A metal oxide material as set forth in claim 1, wherein the Pb/Bi ratio is less than 1, and the Ca/Sr ratio is about
 1. 5. A metal oxide material according to claim 4 wherein −1≦δ≦1.
 6. A metal oxide material as set forth in claim 4 wherein the value of δ is fixed by annealing said metal oxide material at a temperature of 300-550° C. in air or at an oxygen pressure or partial pressure and temperature equivalent to annealing in air within said temperature range.
 7. A metal oxide material according to claim 1, wherein x is 2.1.
 8. A metal oxide material having the formula Bi_(2.2−x)Pb_(x)Sr₂Ca₂Cu₃O_(10+δ), wherein 0<x≦0.4.
 9. A metal oxide material as set forth in claim 8 wherein 0.15≦x≦0.4.
 10. A metal oxide material as set forth in claim 8 wherein 0.30≦x≦0.4.
 11. A metal oxide material as set forth in claim 8 wherein x is about 0.35.
 12. A metal oxide material as set forth in claim 8 wherein δ is fixed by annealing said metal oxide material at a temperature of 300-550° C. in air or at an oxygen pressure or partial pressure and temperature equivalent to annealing in air within said temperature range.
 13. A metal oxide material having the formula (Bi,Pb)_(x)Sr₂Ca₂Cu₃O_(10+δ), wherein x is about 2.1 and Bi is partially substituted by Pb.
 14. A metal oxide material as set forth in claim 13 wherein δ is fixed by annealing said metal oxide material at a temperature of 300-550° C. in air or at an oxygen pressure or partial pressure and temperature equivalent to annealing in air within said temperature range.
 15. A metal oxide material as set forth in claim 13 wherein δ is fixed by annealing said metal oxide material at a temperature of about 500° C. in air followed by quenching in liquid nitrogen.
 16. A metal oxide material according to claim 13, wherein x is 2.1.
 17. A metal oxide material having a layered crystal structure comprising, in sequence, layers of BiO, SrO, CuO₂, Ca, CuO₂, Ca, CuO₂, SrO, BiO, wherein Bi may be substituted by Pb, and having a bulk composition of (Bi,Pb)_(x)Sr₂Ca₂Cu₃O_(10+δ), wherein x is about 2.1.
 18. A metal oxide material according to claim 17 having a bulk composition of (Bi,Pb)_(2.1)Sr₂Ca₂Cu₃O_(10+δ.)
 19. A metal oxide material having a layered crystal structure comprising, in sequence, layers of BiO, SrO, CuO₂, Ca, CuO₂, Ca, CuO₂, SrO, BiO, wherein Bi may be substituted by Pb, and having a bulk composition of (Bi,Pb)_(x)Sr₂Ca₂Cu₃O_(10+δ), wherein x is about 2.2. 